KR101019030B1 - Circuit braeker with rebound preventor - Google Patents

Abstract

The present invention relates to a circuit breaker having a rebound prevention mechanism, comprising: a main body; A fixed contact fixed to the main body; A movable contact in contact with or separated from the fixed contact and movably installed in the main body; A main shaft connected to one end of the movable contact and rotatably installed on the main body; A trip mechanism part coupled to the other side of the main shaft to rotate the main shaft; And a rebound prevention member having one end rotatably installed on the main body, and a rebound prevention member having a locking part engaged with the main shaft at the other end, wherein the rebound prevention member rotates by being engaged with the main shaft. The engaging portion is provided with a circuit breaker for blocking the reverse rotation of the main shaft when the rebound prevention member is rotated for a predetermined range or more.

breaker. Rebound, trip mechanism, catch.

Description

CIRCUIT BRAEKER WITH REBOUND PREVENTOR

The present invention relates to a circuit breaker having a rebound prevention mechanism, and more particularly to a circuit breaker having a mechanism for preventing the rebound operation during the trip operation of the circuit breaker for protecting the circuit from overcurrent or short circuit accident.

Breaker is an electric device installed on the electric line to protect the power system and power equipment by safely cutting off the current when the line is opened or closed artificially under normal use or when an accidental current such as a ground fault or short circuit occurs. Typically, the circuit portion of such a circuit breaker consists of a spring and a rigid body to enable rapid operation during a trip, i.e. a circuit off operation. 1 and 2 show part of the tripping operation of these breakers.

1 is a side view showing a side of a part of the trip operation part, and FIG. 2 is a front view showing a front view. 1 and 2, the breaker 10 includes a mobile contact 12 therein, and the contact 12 performs a trip operation while being in contact with or separated from a fixed contact not shown. . A push rod 14 made of an insulator is connected to one end of the movable contact 12, and the other end of the push rod 14 is connected to one end of the main shaft 18 via a contact spring 16. Connected.

The main shaft 18 is rotatably mounted about the rotation shaft 20, and a trip spring 22 is connected near the other end thereof. The trip spring 22 and the contact spring 16 serve to rotate the main shaft 18 clockwise in FIG. 1 during a trip operation.

On the other hand, the rotation of the main shaft 18 is limited to a certain range by a damping mechanism, the other end of the main shaft 18 is connected to the rotary link 26 by the rod 24, the rotary link The rotation of 26 is limited within a certain range by the stop block 28. Thus, when the main shaft 18 rotates clockwise, the rod 24 moves upward in FIG. 2, whereby the rotary link 26 rotates counterclockwise and stops by the stop block 28. Done.

In practice, however, the rotary link 26 collides with the stop block 28 due to the repulsive force and then moves in the opposite direction to narrow the gap between the movable contact 12 and the fixed contact, which is called rebound, This rebound phenomenon is repeated several times while reducing its amplitude. For this reason, since the insulation between poles cannot be maintained, a trip operation becomes incomplete.

In order to prevent this, an oil dash pot 30 is installed in the stop block 28 to reduce the rebound phenomenon through the attenuation action of the oil dash pot. The oil dash pot uses the attenuation action of the oil filled therein, but when the flow rate is small, it can absorb a large shock, but the time until the attenuation is reached is too long, and when the flow rate is large, the rebound amount becomes large. There is. That is, as shown in FIG. 3, when the oil flow rate is small, the time until the vibration due to rebound is completely attenuated is relatively short, but the stroke amount is increased. When the oil flow rate is large, the stroke amount is small. It can be seen that the time until the vibration due to the rebound is completely attenuated is long (see FIG. 4).

In addition, the oil dash pot does not have a constant shock absorbing amount, so the rebound amount cannot be adjusted as desired by the designer. As time passes, its characteristics change due to leakage. In addition, when the circuit breaker is gradually enlarged as in the present time, since the impact amount generated at the trip is also increased, the oil dashpot must be increased accordingly, but there are limitations due to economic and spatial constraints.

The present invention has been made to overcome the disadvantages of the prior art as described above, the technical problem is to provide a circuit breaker having a rebound prevention mechanism that can effectively prevent the rebound during the trip operation of the circuit breaker.

The present invention to achieve the above technical problem, the main body; A fixed contact fixed to the main body; A movable contact in contact with or separated from the fixed contact and movably installed in the main body; A main shaft connected to one end of the movable contact and rotatably installed on the main body; A trip mechanism part coupled to the other side of the main shaft to rotate the main shaft; And a rebound prevention member having one end rotatably installed on the main body, and a rebound prevention member having a locking part engaged with the main shaft at the other end, wherein the rebound prevention member rotates by being engaged with the main shaft. The engaging portion is provided with a circuit breaker for blocking the reverse rotation of the main shaft when the rebound prevention member is rotated for a predetermined range or more.

Preferably, the locking portion is a locking groove formed in the rebound prevention member, the main shaft may be formed with a projection for engaging the groove. Here, the locking groove may be formed to increase the distance from the inlet to the inside.

On the other hand, the locking groove includes a first contact surface in contact with the protruding portion during the forward rotation of the rebound prevention member, and a second contact surface facing the first contact surface, wherein the first contact surface is an end portion of the second contact surface. It can be extended to the outside. Here, the first contact surface may be formed as a curved surface of an arc shape. In addition, a discontinuous surface extending toward the first contact surface may be formed on the second contact surface.

According to another aspect of the invention, the main body; A fixed contact fixed to the main body; A movable contact in contact with or separated from the fixed contact and movably installed in the main body; A main shaft connected to one end of the movable contact and rotatably installed on the main body; A trip mechanism part coupled to the other side of the main shaft to rotate the main shaft; And a rebound prevention member having one end rotatably installed on the main body, and the other end having a rebound preventing member having a catch portion engaged with the main shaft, wherein the catch portion includes first and second contact surfaces facing each other. The engaging groove is formed, wherein the first contact surface is in contact with a portion of the main shaft when the movable contact is separated to rotate the rebound prevention member in the opposite direction to the main shaft, the second contact surface is the rebound prevention member When contacted with a portion of the main shaft in a state of rotation over a certain range is provided a breaker for blocking the reverse rotation of the main shaft.

Preferably, the end portion of the first contact surface may extend outwardly than the end portion of the second contact surface. Here, the first contact surface may be formed as a curved surface of an arc shape.

According to still another aspect of the present invention, in the breaker which is connected to both ends of the main mechanism that is rotatably installed in the main body and the trip mechanism and the movable contact, transfer the tensile force of the trip mechanism to the movable contact to perform the trip operation And a locking groove formed to engage with a portion of the main shaft, and further including a rebound prevention member rotatably installed in the breaker, wherein the locking groove is in contact with a portion of the main shaft when the main shaft is rotated. A breaker is provided, including first and second contact surfaces, wherein an extension line of a force applied by a portion of the main shaft to the second contact surface when the main shaft is reversely rotated passes through the center of rotation of the rebound preventing member.

Here, the main shaft may include a protrusion inserted into the locking groove during forward and reverse rotation.

According to still another aspect of the present invention, in the breaker which is connected to both ends of the main mechanism that is rotatably installed in the main body and the trip mechanism and the movable contact, transfer the tensile force of the trip mechanism to the movable contact to perform the trip operation And a locking groove formed to engage with a portion of the main shaft, and further including a rebound prevention member rotatably installed in the breaker, wherein the locking groove is in contact with a portion of the main shaft when the main shaft is rotated. A breaker is provided, including first and second contact surfaces, wherein a reverse rotation of the main shaft is not performed when a part of the main shaft is in contact with the second contact surface.

According to the aspects of the present invention having the configuration as described above, since the rebound by the rebound prevention member is prevented by the repulsive force after the trip operation can increase the reliability of the trip operation.

Hereinafter, with reference to the accompanying drawings will be described in detail an embodiment of a circuit breaker according to the present invention.

Referring to FIG. 5, an embodiment of a circuit breaker according to the present invention is illustrated, and in the following description, the same components as those shown in FIGS. 1 and 2 will be denoted by the same reference numerals, and redundant description thereof will be omitted. do.

The embodiment 100 shown in FIG. 5 basically has a structure similar to the example shown in FIG. 1, but with a catch lever 18a extending radially outward from around the rotation axis 20 of the main shaft 18. Is formed, and a catch lever pin 18b as a projection is formed so as to protrude from the surface of the catch lever 18a.

Meanwhile, referring to FIG. 6, a fixing bracket 40 is provided in the breaker main body, and the rebound catch 30 as a rebound prevention member freely centers on the hinge shaft 42 at a position adjacent to the catch lever 18a. It is installed to be rotatable. In FIG. 6, the rebound catch 30 is made of a thin plate-like material, and is arranged side by side along the lower side in FIG. 6 in the state where no external force is applied due to its own weight.

The rebound catch 30 is formed with a catching groove 32 extending in width from the inlet to the inside, and the two contacting surfaces of the catching grooves 32 are opposed to each other by the first contact surface 32a and the second contact surface, respectively. Referred to as 32b. Here, an end portion of the first contact surface 32a is positioned to protrude outwardly, that is, toward the main shaft 18, relative to the end portion of the second contact surface 32b. In addition, the surface of the first contact surface 32a is curved, and the curve is bent toward the catch lever pin 18b. The curve has an arc, but may be a variety of other continuous curves.

Referring now to Figures 7 to 10, the operation of this embodiment will be described. 7 shows a state before the trip operation is performed. In this state, since no external force is applied to the rebound catch 30, the rebound catch 30 is disposed downward by its own weight. Thereafter, when the trip operation is performed, the main shaft 18 is rotated clockwise, so that the catch lever pin 18b comes into contact with the first contact surface 32a in the locking groove 32. When the main shaft 18 continues to rotate, the rebound catch 30 is rotated counterclockwise by the catch lever pin 18b as shown in FIG. 8, with the catch lever pin 18b. Is inserted into the locking groove (32).

When the trip operation is completed and the main shaft 18 is rotated to the maximum, the main shaft 18 is rotated counterclockwise by the repulsive force of the contact spring 16 and the trip spring 22 as described above. 9, the catch lever pin 18b comes into contact with the second contact surface 32b. As a result, counterclockwise rotation of the main shaft 18 is prevented, whereby the rebound of the main shaft 18 is quickly limited within a predetermined range. Here, the rotation of the main shaft 18 in the clockwise direction is called forward rotation, and the rotation in the counterclockwise direction is called reverse direction.

The rebound operation of the main shaft 18 will be described in detail. Immediately after the main shaft 18 is rotated to the maximum by the trip operation, the reversal force is reversed at a very high speed by the repulsive force. Therefore, even before the rebound catch 30 starts to rotate in the clockwise direction, the main shaft 18 rotates in the reverse direction so that the second contact surface (with the rebound catch 30 rotated to the maximum in the counterclockwise direction). 32b). In this state as well, the main shaft 18 exerts a force on the rebound catch 30, but the direction of action of the force passes through the center of the hinge axis 42 of the rebound catch 30. Force applied to the rebound catch 30 does not produce the torque to rotate the rebound catch 30.

Due to this, the force applied by the main shaft 18 is canceled by the reaction force applied by the hinge shaft 42 so that the main shaft 18 can no longer rotate and this provides the effect of preventing rebound. do. In other words, the rotation of the main shaft 18 is impossible when the catch lever pin 18b is in contact with the second contact surface 32b.

Meanwhile, the second contact surface 32b may contact the catch lever pin 18b only when the rebound catch 30 is rotated by a predetermined range or more.

The main shaft 18, which is prevented from being rotated by the rebound catch 30, rotates forward again by the force of the contact spring 16 and the trip spring 22. Finally, as shown in FIG. 8, the first contact surface ( It remains in contact with 32a).

After that, when the main shaft 18 is reversely rotated through the trip mechanism in order to reconnect the circuit by contacting the movable contact with the fixed contact again, the first contact surface 32a is released. Since the rotation is made in contact with the catch lever pin 18b, the main shaft 18 can be smoothly rotated in the reverse direction.

In the above embodiment, the rebound amount may be arbitrarily determined by those skilled in the art by adjusting the width of the locking groove or the length of the second contact surface. In addition, since the rebound catch does not require a separate mechanism such as a spring, and operates by its own weight, the rebound catch does not have a problem such as changing the characteristics of the operation even if used for a long time.

On the other hand, the second contact surface of the rebound catch may be configured as a continuous surface as shown in the example shown in Figure 5, but is not necessarily limited to this to catch the catch lever pin ( It may further include a discontinuous surface, for example, a locking step for preventing the movement of 18b). That is, as shown in FIG. 11, an example in which the second contact surface 32b 'of the rebound catch 30' is formed as a discontinuous surface where two straight lines meet may be considered.

1 is a side view showing a conventional general circuit breaker.

FIG. 2 is a front view of the circuit breaker shown in FIG. 1. FIG.

3 is a graph showing the relationship between the oil amount and the rebound amount in the circuit breaker shown in FIG.

4 is an enlarged graph illustrating a case where the amount of oil is small in the graph illustrated in FIG. 3.

Figure 5 is an equivalent to Figure 1 showing one embodiment of a circuit breaker according to the invention.

FIG. 6 is an enlarged side view of the rebound catch part of the embodiment illustrated in FIG. 5.

7 to 10 are explanatory views showing the operation of the embodiment shown in FIG.

11 is a side view showing another embodiment of the rebound catch.

Claims (12)

main body; A fixed contact fixed to the main body; A movable contact in contact with or separated from the fixed contact and movably installed in the main body; A main shaft connected to one end of the movable contact and rotatably installed on the main body; A trip mechanism part coupled to the other side of the main shaft to rotate the main shaft; And A circuit breaker comprising a rebound prevention member having one end rotatably installed on the main body, and the other end having a latching portion engaged with the main shaft. The rebound prevention member is engaged with the main shaft to rotate together, the latching portion is a circuit breaker to block the reverse rotation of the main shaft when the rebound prevention member is rotated more than a predetermined range. The method of claim 1, The catching portion is a catching groove formed in the rebound preventing member, the breaker, characterized in that the main shaft is formed with a projection for engaging the groove. The method of claim 2, The locking groove is characterized in that the gap increases from the inlet toward the inner side. The method of claim 2, The locking groove includes a first contact surface which contacts the protrusion when the rebound prevention member rotates in the forward direction, and a second contact surface that faces the first contact surface. And wherein the first contact surface extends outwardly than an end of the second contact surface. The method of claim 4, wherein The first contact surface is a circuit breaker, characterized in that formed in a curved shape of an arc. The method of claim 4, wherein Breaker, characterized in that the second contact surface is formed with a discontinuous surface extending toward the first contact surface side. main body; A fixed contact fixed to the main body; A movable contact in contact with or separated from the fixed contact and movably installed in the main body; A main shaft connected to one end of the movable contact and rotatably installed on the main body; A trip mechanism part coupled to the other side of the main shaft to rotate the main shaft; And A circuit breaker comprising a rebound prevention member having one end rotatably installed on the main body, and the other end having a latching portion engaged with the main shaft. The locking portion is provided with a locking groove including a first and second contact surface facing each other, The first contact surface contacts a portion of the main shaft when the movable contact is separated to rotate the rebound preventing member in a direction opposite to the main shaft, The second contact surface is a circuit breaker to block the reverse rotation of the main shaft when the rebound preventing member is in contact with a portion of the main shaft in a state of being rotated for a predetermined range or more. The method of claim 7, wherein An end portion of the first contact surface extends outwardly than an end portion of the second contact surface. The method of claim 8, The first contact surface is a circuit breaker, characterized in that formed in a curved shape of an arc. In the breaker which is connected to the both ends of the main mechanism that is rotatably installed in the main body and the trip mechanism and the movable contact, and transmits the tensile force of the trip mechanism to the movable contact to perform a trip operation, A locking groove is formed to engage with a portion of the main shaft, and further includes a rebound prevention member rotatably installed in the breaker. The locking groove includes first and second contact surfaces contacting a part of the main shaft when the main shaft rotates, and a part of the main shaft is applied to the second contact surface when the main shaft is reversely rotated. Breaker through which the extension line of force passes through the center of rotation of the rebound prevention member. The method of claim 10, The main shaft is a circuit breaker, characterized in that it comprises a projection which is inserted into the locking groove during forward and reverse rotation. In the breaker which is connected to the both ends of the main mechanism that is rotatably installed in the main body and the trip mechanism and the movable contact, and transmits the tensile force of the trip mechanism to the movable contact to perform a trip operation, A locking groove is formed to engage with a portion of the main shaft, and further includes a rebound prevention member rotatably installed in the breaker. The locking groove may include first and second contact surfaces contacting a part of the main shaft when the main shaft rotates, and in a state in which a part of the main shaft contacts the second contact surface, reverse rotation of the main shaft may occur. Circuit breaker.

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